The Electrochemical Nature of Non-Faradaic Catalysis at Interfaces

The Electrochemical Nature of Non-Faradaic Catalysis at Interfaces

Electric fields are known to play an important role in many catalytic transformations throughout chemistry and biology. In principle, oriented electric fields could also be used to control thermochemical catalysis at solid-liquid interfaces. Yet, the role of electrical polarization in non-faradaic h...

Full description

Bibliographic Details
Main Author:	Wesley, Thejas S.
Other Authors:	Surendranath, Yogesh
Format:	Thesis
Published:	Massachusetts Institute of Technology 2023
Online Access:	https://hdl.handle.net/1721.1/151211

Similar Items

Exploring faradaic and non-faradaic electrochemical impedance spectroscopy approaches in Parkinson's disease diagnosis
by: Hussaini Adam, et al.
Published: (2024-03-01)

Inflammatory Stimuli Responsive Non-Faradaic, Ultrasensitive Combinatorial Electrochemical Urine Biosensor
by: Antra Ganguly, et al.
Published: (2022-10-01)

Non-Faradaic optoelectrodes for safe electrical neuromodulation
by: Jian Chen, et al.
Published: (2024-01-01)

Spontaneous Electric Fields Play a Key Role in Thermochemical Catalysis at Metal−Liquid Interfaces
by: Wesley, Thejas S, et al.
Published: (2022)

Recent developments in faradaic bioelectrochemistry
by: Armstrong, F, et al.
Published: (2000)

Recent trends in non-faradaic supercapacitor electrode materials
by: Onyeka Stanislaus Okwundu, et al.
Published: (2019-07-01)

Green synthesized silver nanoparticles functionalized interdigitated electrodes for bacterial sensing using non-faradaic electrochemical impedance spectroscopy
by: Rhea Patel, et al.
Published: (2023-12-01)

Physical, Chemical, and Electrochemical Properties of Redox-Responsive Polybenzopyrrole as Electrode Material for Faradaic Energy Storage
by: Bushra Begum, et al.
Published: (2021-08-01)

Reliable reporting of Faradaic efficiencies for electrocatalysis research
by: Paul A. Kempler, et al.
Published: (2023-03-01)

Diffuse charge and Faradaic reactions in porous electrodes
by: Biesheuvel, P. M., et al.
Published: (2011)

Scalable electrosynthesis of commodity chemicals from biomass by suppressing non-Faradaic transformations
by: Hua Zhou, et al.
Published: (2023-09-01)

Calculation of the Faradaic Impedance of the Electrode–Tissue Interface Improves Prediction of Behavioral T/C Levels in Cochlear Implant Patients
by: Andrzej Zarowski, et al.
Published: (2023-09-01)

Faradaic electro-swing reactive adsorption for CO2 capture
by: Voskian, Sahag, et al.
Published: (2020)

Enhancing the Faradaic efficiency of solid oxide electrolysis cells: progress and perspective
by: Prashik S. Gaikwad, et al.
Published: (2023-08-01)

Intercalation Engineering of 2D Materials at Macroscale for Smart Human–Machine Interface and Double‐Layer to Faradaic Charge Storage for Ions Separation
by: Rahul Patil, et al.
Published: (2023-03-01)

Potential window alignment regulating ion transfer in faradaic junctions for efficient photoelectrocatalysis
by: Hongzheng Dong, et al.
Published: (2023-12-01)

Electrochemically mediated separations and catalysis
by: Voskian, Sahag.
Published: (2020)

Simultaneous Observation of Faradaic and Tunneling Current at a Flat Surface Using Tunneling-Current-Based Constant-Distance Scanning Electrochemical Microscopy with a Platinum Nanoelectrode
by: Hiroshi YAMADA, et al.
Published: (2021-05-01)

Faradaic Pixels for Precise Hydrogen Peroxide Delivery to Control M‐Type Voltage‐Gated Potassium Channels
by: Oliya S. Abdullaeva, et al.
Published: (2022-01-01)

Ultrafast chronoamperometry of acoustically agitated solid particulate suspensions: Nonfaradaic and faradaic processes at a polycrystalline gold electrode
by: Rees, N, et al.
Published: (2004)

Electrochemical activation of catalysis : promotion, electrochemical promotion, and metal-support interactions /
by: Vayenas, C. G. (Costas G.)
Published: (2001)

Imaging Analysis of Scanning Electrochemical Microscopy in Energy Catalysis
by: Xinfang Zhang, et al.
Published: (2023-03-01)

Photoredox catalysis harvesting multiple photon or electrochemical energies
by: Mattia Lepori, et al.
Published: (2023-07-01)

Faradaic Impedimetric Immunosensor for Label-Free Point-of-Care Detection of COVID-19 Antibodies Using Gold-Interdigitated Electrode Array
by: Lian C. T. Shoute, et al.
Published: (2023-12-01)

Encyclopaedia of surface, interface science & catalysis : chemistry & applications /
by: Diaz, Franklin
Published: (2012)

Lignin‐derived carbon materials for catalysis and electrochemical energy storage
by: Huan Wang, et al.
Published: (2022-12-01)

Homogeneous functional self-assembled monolayers: Faradaic impedance baseline signal drift suppression for high-sensitivity immunosensing of C-reactive protein
by: Kanyong, P, et al.
Published: (2019)

Fabricating random arrays of boron doped diamond nano-disc electrodes: Towards achieving maximum Faradaic current with minimum capacitive charging
by: Xiao, L, et al.
Published: (2008)

Realistic Modelling of Dynamics at Nanostructured Interfaces Relevant to Heterogeneous Catalysis
by: Kevin Rossi, et al.
Published: (2022-01-01)

Expanding the scope of powerful electrochemical methods by exploiting nanoconfined cascade catalysis
by: Herold, RA
Published: (2023)

Homogeneous catalysis of electrochemical reactions: “Split waves” at the rotating disc electrode
by: Compton, R, et al.
Published: (1990)

Homogeneous catalysis of electrochemical reactions. Channel electrode voltammetry and the EC′ mechanism
by: Compton, R, et al.
Published: (1992)

An Electrochemical Approach to Follow and Evaluate the Kinetic Catalysis of Ricin on hsDNA
by: George Oliveira, et al.
Published: (2021-04-01)

An Electrochemical Study of Gold Dissolution in Thiosulfate Solution with Cobalt–Ammonia Catalysis
by: Ke Li, et al.
Published: (2022-02-01)

Reaction Condition Dependence of Different Overpotential Components in Electrochemical Hydrogen Catalysis
by: Tang, Bryan Y.
Published: (2024)

Catalysis and reactor engineering for the electrochemical conversion of carbon dioxide to carbon monoxide
by: Brown, Steven M.(Steven Michael)
Published: (2020)

How many molecules are required to obtain a steady faradaic current from mediated electron transfer at a single nanoparticle on a supporting surface?
by: Kätelhön, E, et al.
Published: (2014)

Atomically precise Au nanoclusters for electrochemical hydrogen evolution catalysis: Progress and perspectives
by: Xin Zhu, et al.
Published: (2023-12-01)

Defect‐Derived Catalysis Mechanism of Electrochemical Reactions in Two‐Dimensional Carbon Materials
by: Yun Han, et al.
Published: (2023-10-01)

Electrochemical Reoxidation Enables Continuous Methane-to-Methanol Catalysis with Aqueous Pt Salts
by: Kim, R. Soyoung, et al.
Published: (2020)